The in vitro assessment of resin coating materials containing calcium phosphate, bioactive glass, and polylysine for glass ionomer cement restorations.

Biomaterial investigations in dentistry Pub Date : 2025-01-14 eCollection Date: 2025-01-01 DOI:10.2340/biid.v12.42783

Jiraporn Jiramongkhonsuk, Suyada Runglikhitcharoen, Parichart Naruphontjirakul, Piyaphong Panpisut

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Abstract

Objective: Glass ionomer cements (GICs) require protective surface coatings to enhance their clinical performance. This study developed novel protective resin coatings for GICs containing monocalcium phosphate monohydrate (MCPM), bioactive glass nanoparticles (BAGs), and poly-L-lysine (PLS) and evaluated their physical, mechanical, and biological properties when applied to GICs.

Materials and methods: Experimental resin coating materials were formulated with 5-10 wt% of MCPM, BAGs, and PLS. The degree of monomer conversion was measured usingAttenuated total reflectance-Fourier transform infrared spectroscopy (ATR-FTIR) (n = 6). GICs coated with the experimental materials were evaluated for biaxial flexural strength and modulus after 24 h water immersion using a universal testing machine (n = 8). Vickers surface microhardness up to 4 weeks of water immersion was also determined (n = 5). Fluoride and elemental release in water were analyzed using a fluoride-specific electrode and inductively coupled plasma optical emission spectrometry (n = 3). Cell viability was assessed using an MTT assay with mouse fibrosarcoma (n = 3). A commercial resin coating (EQUIA Forte Coat, EQ) served as control. Data were analyzed using one-way ANOVA and Tukey HSD test.

Results: While EQ showed higher monomer conversion (87%) compared to experimental materials (72-74%) (p < 0.05), GICs coated with experimental materials demonstrated comparable strength to EQ-coated GICs. The experimental coatings exhibited similar F, Al, Na, and Si releases to EQ-coated GICs, with enhanced P release. All experimental coatings exhibited comparable cell viability (>70%) to the commercial material.

Conclusion: The novel GIC protective coatings containing MCPM, BAGs, and PLS demonstrated acceptable in vitro performance comparable to commercial materials while potentially offering enhanced remineralization through increased elemental release.

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含磷酸钙、生物活性玻璃和聚赖氨酸的树脂涂层材料用于玻璃离聚体水泥修复的体外评估。

目的：玻璃离子水门栓（GICs）需要保护表面涂层来提高其临床性能。本研究开发了一种新型的GICs保护树脂涂层，该涂层含有一水磷酸钙（MCPM）、生物活性玻璃纳米颗粒（BAGs）和聚l -赖氨酸（PLS），并评估了它们在GICs上的物理、机械和生物性能。材料和方法：用5-10 wt%的MCPM、BAGs、使用衰减全反射-傅里叶变换红外光谱（ATR-FTIR）测量单体转化程度（n = 6）。使用通用试验机（n = 8）评估涂有实验材料的GICs在24小时水浸后的双轴弯曲强度和模量（n = 8）。还测定了高达4周水浸后的维氏表面显微硬度（n = 5）。使用氟化物特异性方法分析了水中氟化物和元素释放采用MTT法对小鼠纤维肉瘤（n = 3）进行细胞活力评估。采用商用树脂涂层（EQUIA Forte Coat， EQ）作为对照。数据分析采用单因素方差分析和Tukey HSD检验。结果：EQ的单体转化率（87%）高于实验材料（72-74%）（p < 0.05），而实验材料包覆的GICs强度与EQ包覆的GICs相当。实验涂层表现出与eq涂层相似的F、Al、Na和Si释放，但P释放增强。所有实验涂层都显示出与商业材料相当的细胞活力（bbb70 %）。结论：含有MCPM、BAGs和PLS的新型GIC防护涂层在体外表现出可接受的性能，与商业材料相当，同时可能通过增加元素释放来增强再矿化。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Biomaterial investigations in dentistry

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审稿时长

14 weeks